ABSTRACT: Diatoms are an ecologically important group of eukaryotic microalgae with properties that make them attractive for biotechnological applications such as biofuels, foods, cosmetics and pharmaceuticals. Phaeodactylum tricornutum is a model diatom with defined culture conditions, but routine genetic manipulations are hindered by a lack of simple and robust genetic tools. One obstacle to efficient engineering of P. tricornutum is that the current selection methods for P. tricornutum transformants depend on the use of a limited number of antibiotic resistance genes. An alternative and more cost-effective selection method would be to generate auxotrophic strains of P. tricornutum by knocking out key genes involved in amino acid biosynthesis, and using plasmid-based copies of the biosynthetic genes as selective markers. Previous work on gene knockouts in P. tricornutum used biolistic transformation to deliver CRISPR-Cas9 system into P. tricornutum. Biolistic transformation of non-replicating plasmids can cause undesired damage to P. tricornutum due to random integration of the transformed DNA into the genome. Subsequent curing of edited cells to prevent long-term overexpression of Cas9 is very difficult as there is currently no method to excise integrated plasmids. This protocol adapts a new method to deliver the Cas9 or TevCas9 system into P. tricornutum via conjugation of plasmids from a bacterial donor cell. The process involves: 1) design and insertion of a guideRNA targeting the P. tricornutum urease gene into a TevCas9 expression plasmid that also encodes a conjugative origin of transfer, 2) installation of this plasmid in Escherichia coli containing a plasmid (pTA-Mob) containing the conjugative machinery, 3) transfer of the TevCas9 expression plasmid into P. tricornutum by conjugation, 4) screening of ex-conjugants for urease knockouts using T7 Endonuclease I and phenotypic screening, and 5) curing of the plasmid from edited cells.